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Model

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Name

obeyesekere1

Derived from:

obeyesekere1

Notes

Substance units

None

Time units

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Volume units

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Area units

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Length units

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Reaction extent units

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A model of cell cycle behavior dominated by kinetics of a pathway stimulated by growth factors.

MN Obeyesekere
SO Zimmerman
ES Tecarro
G Auchmuty

Bull. Math. Biol. 1999; 61 (5): 917-934

PubMed: 17886749
ISSN: 0092-8240
URL: https://ncbi.nlm.nih.gov/pubmed/17886749

Abstract

A modified version of a previously developed mathematical model [Obeyesekere et al., Cell Prolif. (1997)] of the G1-phase of the cell cycle is presented. This model describes the regulation of the G1-phase that includes the interactions of the nuclear proteins, RB, cyclin E, cyclin D, cdk2, cdk4 and E2F. The effects of the growth factors on cyclin D synthesis under saturated or unsaturated growth factor conditions are investigated based on this model. The solutions to this model (a system of nonlinear ordinary differential equations) are discussed with respect to existing experiments. Predictions based on mathematical analysis of this model are presented. In particular, results are presented on the existence of two stable solutions, i.e., bistability within the G1-phase. It is shown that this bistability exists under unsaturated growth factor concentration levels. This phenomenon is very noticeable if the efficiency of the signal transduction, initiated by the growth factors leading to cyclin D synthesis, is low. The biological significance of this result as well as possible experimental designs to test these predictions are presented.

Unit definitions 0

Unit definitions have no effect on the numerical analysis of the model. It remains the responsibility of the modeler to ensure the internal numerical consistency of the model. If units are provided, however, the consistency of the model units will be checked.

Name	Definition

Compartments 1

Id	Name	Spatial dimensions	Size
cell_1	cell	3.0	1.0

Species 7

Id	Name	Initial quantity	Compartment	Fixed
D_1	D	0.1	cell_1 (cell)	✘
E2F_1	E2F	0.0	cell_1 (cell)	✘
E_1	E	0.6	cell_1 (cell)	✘
RP_1	RP	0.0	cell_1 (cell)	✘
RS_1	RS	1.0	cell_1 (cell)	✘
R_1	R	0.5	cell_1 (cell)	✘
X_1	X	0.7	cell_1 (cell)	✘

Initial assignments 0

Initial assignments are expressions that are evaluated at time=0. It is not recommended to create initial assignments for all model entities. Restrict the use of initial assignments to cases where a value is expressed in terms of values or sizes of other model entities. Note that it is not permitted to have both an initial assignment and an assignment rule for a single model entity.

Definition

Reactions 10

Id	Name	Reaction Equation and Kinetic Law
_1	cycD/CDK4 synthesis	∅ > D_1 aD_1 * (k_1 * GF_1 / (1 + k_1 * GF_1))
_7	pRB/E2F complex deassociation via cycE/CDK2	RS_1 > ∅ pE_1 * RS_1 * E_1 / (qE_1 + RS_1 + E_1)
cycECDK2degradation_1	cycE/CDK2 degradation	E_1 > ∅ dE_1 * X_1 * E_1
cyclebreak_1	cycle break	X_1 > ∅ dX_1 * X_1
cycleprogression_1	cycle progression	∅ > X_1 aX_1 * E_1 + f_1 * E2F_1 + g_1 * pow(X_1, 2) * E_1
cyclinCDK4degradation_1	cycD/CDK4 degradation	D_1 > ∅ dD_1 * E_1 * D_1
cyclin_1	cycE/CDK2 synthesis	∅ > E_1 aE_1 * (1 + af_1 * E2F_1)
pRBE2Fcomplexassociation_1	pRB/E2F complex association	R_1 > RS_1 pS_1 * E2F_1 * R_1
pRBE2FcomplexdeassociationviacycDCDK4_1	pRB/E2F complex deassociation via cycD/CDK4	RS_1 > ∅ pD_1 * RS_1 * D_1 / (qD_1 + RS_1 + D_1)
pRBpdephosphorylation_1	pRB-p dephosphorilation	∅ > R_1 pX_1 * RP_1 * X_1 / (qX_1 + RP_1 + X_1)

Parameters 0 21

Global parameters

Id	Value
GF_1	6.3
RT_1	2.5
aD_1	0.4
aE_1	0.16
aX_1	0.08
af_1	0.9
dD_1	0.4
dE_1	0.2
dX_1	1.04
f_1	0.2
g_1	0.528
k_1	0.05
pD_1	0.48
pE_1	0.096
pS_1	0.6
pX_1	0.48
qD_1	0.6
qE_1	0.6
qX_1	0.8
theta_1	1.5
unpho_RB	0.0

Local parameters

Id	Value	Reaction

Rules 0 0 3

Assignment rules

Definition
E2F_1 = theta_1 - RS_1
RP_1 = RT_1 - RS_1 - R_1
unpho_RB = R_1 + RS_1

Rate rules

Definition

Algebraic rules

Definition

Function definitions 0

Definition

Events 0

Trigger	Assignments